Stodden DF, Fleisig GS, McLean SP, Lyman SL, Andrews JR. Relationship of pelvis and upper torso kinematics to pitched baseball velocity. Journal of Applied Biomechanics 17(2):164-172, 2001.

Matsuo T, Escamilla RF, Fleisig GS, Barrentine SW, Andrews JF. Comparison of kinematic and temporal parameters between different pitch velocity groups. Journal of Applied Biomechanics 17(1): 1-13, 2001.

Stodden, DF, Fleisig, GS, McLean, SP, Andrews, JR. Relationship of Biomechanical Factors to Basebal Pitching Velocity: Within Pitcher Variation. Journal of Applied Biomechanics 21(1): 44-56, 2005

Methods

In three published studies, Dr. Glenn Fleisig and Dr. James R. Andrews from ASMI worked with other researchers in studying many of the parameters that affect baseball pitch velocity. Two of the studies looked between different pitchers and one study looked at variations within each pitcher. Motions during delivery were analyzed using a high speed (200 frames per second) infrared three-dimensional motion analysis system.

Results

In the study by Matsuo and others, pitchers with higher ball velocity were compared with pitchers with lower ball velocity. Four significant differences were found between these two groups. Compared to the low ball velocity group, the higher ball velocity pitchers demonstrated less lead knee flexion velocity after front foot contact and greater lead knee extension velocity at the time of ball release. Extending the lead knee in this manner may provide stabilization allowing better energy transfer from the trunk to the throwing arm, and could be a critical factor in pitch velocity. Maximum shoulder external rotation and forward trunk tilt at ball release were also greater in the higher velocity group. Greater shoulder external rotation causes a stretch of the internal rotators allowing energy to be stored in these muscles, and creating greater internal rotation during the arm acceleration phase.

Two variations were found in the timing of events. Maximum elbow extension angular velocity and maximum shoulder internal rotation angular velocity occurred earlier in the motion of higher velocity pitchers. The maximum shoulder internal rotation angular velocity also occurred closer to the moment of ball release in the higher velocity pitchers. This optimal timing may aid in generating higher velocity pitches.

Another finding of interest is that early in the pitching motion, the two groups were dissimilar in the timing of their movements, while their later movement timing was much more similar. This implies that early trunk and torso movements are more varied among pitchers than late arm movements.

In the first study by Stodden and others (2001), pelvis and upper torso variables were studied in 19 elite baseball pitchers. The study found that when the arm was completely cocked back (that is, maximum shoulder external rotation, or “MER”), more “open” pelvis and upper torso orientation correlated with increased ball velocity. More open pelvis angle at the time of ball release (REL) also correlated with increased pitch velocity increased. Additionally, pelvis angular velocity from front foot contact to MER, and upper torso angular velocity from MER to REL increased with increased velocity.

The data indicate that a pitcher who is able to position himself properly, and rotate his pelvis and upper torso more quickly is able to generate greater momentum. Theoretically, this increase in momentum leads to greater velocity of the throwing arm and thus greater pitch velocity.

The most recent study by Stodden and others (2005) showed that for a given pitcher, increased elbow flexion torque, shoulder proximal force and elbow proximal force produced greater ball velocity. In addition, the maximum shoulder horizontal adduction occurred later and maximum shoulder internal rotation occurred earlier at greater ball velocities. Higher ball velocity also resulted in decreased shoulder horizontal adduction at foot contact, decreased shoulder abduction during acceleration, and increased trunk tilt forward at ball release.

Conclusion

A pitcher with increased shoulder external rotation, faster pelvis and upper trunk rotation, and greater front knee stabilization and extension will throw with greater ball velocity. Improved timing to maximize arm velocity closer to the time of ball release will also help ball velocity. Increased torque and force produced at both the shoulder and elbow will also lead to greater ball velocity.

Copyright © 2000, American Sports Medicine Institute
December 18, 2007

http://www.asmi.org/asmiweb/research/usedarticles/highlowpitches.htm

This is only a beginner training program. It does not included any joint integrity training, medicine ball training or anaerobic conditioning. To learn a more advanced training program, which includes everything you need to know to increase your athletic performance as a pitcher or position player, check out the 3X Pitching Velocity Program. It is highly recommended!

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To start the analogy we have a car, a hill and a wall. The car is sitting on top of the hill and the wall is built at the bottom. The wall is high enough to just peak over the hood of the car. There is a passenger in the car not wearing a seat belt. To begin, the car starts down the hill at full throttle. The farther it travels, the more speed it gains. It reaches the end of the hill and slams into the wall at full speed. The wall does not break or move. At this point I would like you to really visualize this event. I am sure you have good enough knowledge about classic physics to know what is going to happen to the passenger. Yes, the passenger is propelled through the windshield and flies through the air and lands about 40 feet in front of the car. So, why did this happen? Yes I could throw a bunch of scientific jargon at you but it shouldn’t be this complicated. The passenger flies out of the vehicle after hitting the wall at full speed because it was the only part of the car that wasn’t secured to it. Energy must go somewhere, so when the wall stopped the car, all the momentum transferred to the passenger because it still had the potential to move.

How does this relate to pitching? Good question! The best way for you to understand this comparison is if I describe the correlation. Let’s start with the car. The frame of the car in the analogy of the car crash is the pitchers core. The hill is of course the pitching mound and the wall is when the pitchers front leg lands and stabilizes in his delivery. Now, the front leg is important in this analogy. It is playing the role of the wall. That is no easy role to fill because the wall, in this case, was able to stop the car dead in its tracks. So as the pitchers core travels down the hill, like the car, gains momentum, then the front leg lands and plays the role of the bionic wall. What happens now? Let’s continue to keep this simple. To understand what happens now we must label the last correlation of the car crash analogy. That being the passenger. What is playing the role of the passenger during the pitching delivery? I will tell you! The ball is the passenger. The ball is along for the ride like the passenger and it also is the only part of the ride that isn’t secured to the vehicle or in this case, the pitcher. So, if the front leg does its job of playing the wall, then the ball will be forced to receive all of the momentum generated; in return reaching its top velocity potential.

You may still be a little confused at this point, so to help you pull it all together I will go into more detail about the wall. Let’s bring back up the event of the car crash again. Let’s say the car speeds down the hill and hits the wall but the wall does not hold. It gives away but manages to slow the car some. What happens now to the passenger? The passenger does not fly through the windshield. This occurs because the wall didn’t completely stop the car. It was allowed to continue moving until all the enegry created from the inertia of the car dissipated. Therefore the pasenger was saved because he wasn’t forced to receive all of the momentum from the car. This will be the same case with the ball, if the wall or leg does not stablize completely. This will mean the pitchers front leg will continue to bend instead of hold and the body will not transfer all of the momentum to the ball. For the pitcher to reach his top velocity potential he must stabilize from the front leg all the way up to the chin. The arm and ball should be the only part of the body moving after the chest has extended as far out as it is capable of going. Watch the video above of Edison Volquez performing this almost perfectly. Also view the pic here of Chien-Ming Wang in complete stablization of his front side.

“Loading” is when the pitcher holds his weight back over his back leg, while his front side continues building momentum towards the target. This is why strong legs and core, produce powerful pitching. Look at Eric Gagne in this picture. He is squatting on his back leg, waiting for the perfect time to fire his hips and then his shoulders.

A component of velocity is produced when torque is generated in the two rotational pivots. The rotation of the hips, to the rotation of the shoulders. Tim Lincecum calls this the “Rubber Band.” Think of your core as the “Rubber Band.” Rotating the shoulder and hip pivot separate from each other would tighten the “Rubber Band.” This sounds a lot easier than it actually is to perform. This is why a small amount of athletes can throw a baseball over 90 mph.

The importance of the “Load” is that it holds the weight back until the first pivot, the hips, are ready to build maximum torque. Triple extension in the back leg drives the momentum into front foot strike, forcing the hips to pivot. Then “Separation,” or “Scap Loading” must occur to build torque in the core. There is that word again “Loading”. Notice the pitcher here in this position. His hip rotation is now complete. It has built maximum torque. You can see this in the tightening of his “Rubber Band.” Notice his shirt is stretching like a rubber band would. Now, all that is left to do, is to fire the last pivot, the shoulders forward and then stabilize. Stabilization allows the momentum generated from the body to transfer to the ball.

If the pitcher didn’t “Load” his weight back, as his front side continued to build momentum and set the first pivot of the hips, then top velocity could never be achieved. It would also put more stress on the rotator cuff, because the torque would build more in the shoulders than the core.

The “Load” is also just as important for hitters to develop power. Notice this picture of A-Rod in the “Load” position. The difference is hitters are more compact because they have to defend the strike zone. Therefore, a hitter cannot have a long stride like a pitcher. This brings up another good point. A good stride is considered to be the length of your body height. The “Load” position also increases your stride. So when you here a Coach yell out that you need to stride out more, then you will understand that this means you are not “Loading.” The importance of the “Stride” is that it moves you closer to the plate, shortening the distance the ball must travel, which increases velocity and a good “Stride” gives you more time to build momentum.

In conclusion, a good “Load” position is more valuable for a pitcher than a high lift leg. It generates as much or more momentum but is critical in generating optimal hip to shoulder separation. Here is a gallery of more pitchers in the “Load” position. View gallery here.

I do not own these photos. This is a collection I obtained from the web.

[View with PicLens]

12►

The start of a 40 yard dash is first based on the athlete’s explosive power to help get them from a static position out into the drive phase of the sprint. Many coaches today have their athletes start in a 3 point stance athlete stands with front foot 2-6 inches from line depending on the athletes size and back foot 2-4 inches from front foot with toes facing forward. The athletes front knee should be bent nearly at 90 degrees and back leg around 120 degrees with hips slightly above knees, back flat and chin tucked. The left arm is bent at 90 degrees at the hip if the left leg is in front, and the right arm is on the line with thumb pointing towards your left foot and index finger point to the right. The athlete’s right shoulder is directly over the right hand with the athlete’s weight leaning forward.

Once the athlete has left the static position the athlete is now in the acceleration or drive phase. Michael Gough (2006), defines the acceleration phase from the initial movement of ground contact until the athlete reaches top end speed. A powerful triple extension of the hip, knee, and ankle joints is important for maximum power development off the start. Forward body lean is critical during the acceleration phase with the shoulders always over the hips. Most coaches want the athlete driving out in a 35 to 45 degree angle with elbows at 90 degrees and driving their heel over their knee with foot dorsiflexed and foot striking under hips. In fact, research by Weyand, Sternlight, Bellizzi and Wright (2000) indicated that the force applied at ground contact is the most important determinant of running speed. Ken Jakalski (2008) states in his article that the dorsiflexion of the ankle is the “magic bullet” of the sprint cycle. He explains this of the dorsiflexed ankle because it puts a stretch on the gastrocnemius, soleus and achilles complex which contributes to knee flexion and hip flexion. He goes on to explain that if the athletes does not dorsiflex the ankle, the gastrocnemius soleus and achilles complex cannot help out as a leg flexor. If the gastrocnemius cannot assist in this process, another muscle group will, which are the hamstrings. Hamstrings should not serve a primary role as knee flexors they are hip extenders, not knee flexors. If the hamstrings are called upon to assist in knee flexion, they will be less effective in carrying out their primary responsibility.

The next phase of the forty yard dash is maximal velocity. This takes place for the last 12.66 yards. Michael Young (2007) of the USA Military Academy and Human Performace Consulting explains there are three primary goals of maximal velocity sprinting: preservation of stability, minimizing braking forces and maximization of vertical propulsive forces. Preservation of stability is the body’s ability to stay in perfect posture for the sprint because when stability is disrupted the loss of elasticity occurs. This stability relates to the athletes core for the most part, think of a squat an athlete holds their breath on the way down to support their back and keep their spine protected. The next goal is to minimize braking forcing which is any force that act in the opposite direction of the desired movement. The primary cause of excessive braking forces is making ground contact too far out in front of the athlete’s center of mass. This can go back to the stability goal because if an athlete has good stability the athlete is less likely to lean back or stand strait up which tends to disrupt the foot strike under the hips. The last goal is maximization of vertical propulsive forces which is the distance traveled in the air before ground contact. Vertical propulsive forces help the athlete with a more effective ground contact position and an increase in negative foot speed which when the foot is moving backwards at ground contact with respect with body moving forward; which, in turn helps the athlete accelerate through the line. Another benefit to the maximization of vertical propulsive is an increase in leg stiffness which is the ability of the legs to act like a spring during contact. Actually, Bret, Dufour, Messonnier and Lacour did study on leg strength and stiffness as ability factors in 100 meter sprints and found that leg stiffness is critically important to maximal velocity sprinting and the maintenance of momentum developed during the acceleration period of a sprint.

Throughout this paper one can see that there are many detailed mechanics through a 40 yard sprint. In a recap we know how to start, we know during the drive phase the athletes elbows are firing past the hips to the shoulders at 90 degrees, the heels are driving up over the knee, the shoulders are in advance of the hips and the athlete is making ground contact beneath the athletes hips which helps drive the athlete forward. During max velocity phase the athlete is doing everything that is in the drive phase except now we are trying to aim for more of a vertical propulsive movement. There is many other factors that go into sprinting for instance breathing, power and strength but for the purpose of this paper I am just explaining the mechanics of a sprint.

Now, that sprint mechanics are understood, what are some improper mechanics that athletes usually do and how can they be fixed. For starters many young athletes have problems with mechanics and it starts with their posture. Most young athletes have tight hips, glutes, hamstrings and gastrocnemius, soleus and achilles complex, internally rotated shoulders and an everted foot due to sitting in class all day. Think about if these kids are in flexion all day and that is what their body knows. So, how can these athletes improve their posture and the answer is through corrective exercises. Pete Egoscue suggests in his book Pain Free to do arm circles for internally rotated shoulders, and many other great corrective exercises for the hips, glutes, hamstrings and gastrocnemius, soleus and achilles complex. But, the most important corrective exercise when it comes to sprinting is foot circles. If an athlete has a foot that is everting and supinating the athlete may lose up to 2/3 or more of surface area and all important assistance of the knee and hip and their associated musculature (48). Once foot circle are performed the athlete feels an increase on surface area as well as more strength because of the assistance of the knee and hip so, if an athlete increases surface area, the athlete then increases force and if the athlete increase force the athlete in turn increase speed with proper sprint mechanics. The next error most athletes are with their elbows many athletes kick their arm back to 180 degrees past their hip which turns their arm into a long slow pendulum. Some athletes cross their bodies with their arms and many do not lock their wrist out which can inhibit the stretch reflex mechanism in the athletes shoulder if the hand supinates past the hip. These improper elbow mechanics can be improved by seated arm swings drills and arm circles. Brown and Ferrigno (2005) explain seated arm drills Starting Position: Seated on the floor with the legs straight out in front of you. Swing arms in a sprinting motion. Elbows should be kept at 90 degrees and keep hands relaxed. Your hands should come up to about shoulder height and should go past your hips in the back. Be careful to not bounce off of the floor as you swing your arms faster. Other problems athletes have is driving heel over knee, driving off of their power pads, heel contacting ground and shoulders not over hips. To help improve these faults there are the Mach Drills invented by Gerard Mach. A cornerstone of his system was the A B & C drill series. Mach (1977) broke the stride into its components parts, knee lift, foreleg action and the push off through the drills. The A Drills were designed to work the knee lift component. The B Drills were designed to work on foreleg reach or pawing action. According to Mach All exercises with leg extension and active down are special exercises to strengthen the hamstrings (6). Mach (1977) also explained The marching and skipping exercises were designed to develop the technique required for body lean, arm action, high knee lift, leg extension, and keeping the center of gravity high, but did not emphasize the strong driving forward or push forward action and the C Drills were designed to work on push off and extension (6). Brent McFarlane uses similar drill for improving speed and technique as does Tom Shaw. Other ways to enhance performance is by doing explosive Olympic lifting and plyometrics. In fact, Eduardo S¡ez, Gonz¡lez-Badillo, Juan Jose, Izquierdo did a study on Low and Moderate Plyometric Training and found that the lower training frequency produced a greater jumping and sprinting gain compared to high frequency. Therefore, sometimes as a coach remember less is more.

In closing, one can see how complex and how much detail goes into sprint work. Again, there is much more that goes into sprinting besides mechanics for instance strength, muscle fibers, breathing and etc. Finally, remember that the start and the finish of a sprint are equally important and if you want to run a good 40 yard dash there is much more than just genetics that come into play. In the words Vern Gambetta used in his article about speed drills there are many roads to Rome and another famous idiom there are many ways to skin a cat. What this mean is coach the drills and training that work for your athletes.

References

1. Bret, C., Rahmani, A., Dufour, A.B., Messonnier, L., and Lacour, J.R. (2002). Leg strength and stiffness as ability factors in 100m sprint running. Journal of Sports Medicine and Physical Fitness. 42(3): 274:281.
2. Brown, Lee and Ferrigno, V. (2005). Training for Speed agility and Quickness: Champaign, IL: Human Kinetics.
3. Eduardo S¡ez, Gonz¡lez-Badillo, Juan Jose, Izquierdo, Mike .Low and Moderate Plyometric Training Frequency Produces Greater Jumping and Sprinting Gains Compared with High Frequency. Journal of Strength and Conditioning Research. 22(3): 715-725. 2008.
4. Gough, Michael. The Forty-Yard Dash for the High School Athlete. National Strength and Conditioning Association Journal. 28( 2): 24-25. 2006.
5. Jakalski, Ken. Sprint Technique and Speed Training. 2008. Enhanced Fitness and Performance.http://www.enhancedfp.com/sport-specific/track-and-field/400-meter-training-ken-jakalski
6. Mach, Gerard. Sprinting & Hurdling School. CTFA 1977: Page 6
7. McFarlane, Brent. A Basic and Advanced Technical Model for Speed. National Strength and Conditioning Association Journal. 15(5): 57- 61. 1993.
8. McFarlane, Brent. A Look Inside the Biomechanics and Dynamics of Speed. National Strength and Conditioning Association Journal. 9(5): 35-41. 1987.
9. Pete Egoscue (Author), Roger Gittines (Contributor) (1998). Pain Free: A Revolutionary Method for Stopping Chronic Pain: New York: Bantom.
10. Weyand, P., Sternlight, D., Bellizzi, M. and Wright, S. (2000). Faster top running speeds are achieved with greater ground forces not more rapid leg movements. Journal of Applied Physiology, 89, 1991-2000.
11. Young, Michael. Maximal Velocity Sprint Mechanics. Track Coach. No. 179. Spring 2007.

Before I give you the secrets to top velocity you must first understand how important it is to train the body for this ability. Your training program should be made of lifts and drills that are training fast twitch muscle fibers. I am sure you have heard me say this a million times but there is no better training than the Olympic Lifts. This involves all types of Cleans, along with Squats and some Split Jerks. These lifts force you to move a good amount of weight very quickly, therefore making you a more explosive athlete. Once you have maxed your explosive potential as an athlete you are then ready to find your top velocity as a pitcher. Purchase the 3X Pitching Velocity Program for all these explosive training routines and much more.

In layman’s terms, Velocity as defined by Newton, is force divided by mass. So for you to develop more velocity you either need to increase the force applied to the ball or the application time with the same amount of force. I recommend we do both as pitchers but here I will break them down separately in two questions.

How do we increase force to the ball?

This may seem complicated but in theory it is very simple, so stay with me. To increase force to the ball we must add momentum to our delivery and then stablize that momentum for transfer to ball. Now, this is where we as pitchers go wrong. Most young pitchers when wanting to add force to the ball only add the momentum to the arm. Momentum must be added to the lower half of the body for it to be efficient and effective when delivering the pitch. Let’s use a Javelin thrower to understand this lower half momentum. What a Javelin thrower does is he can run as quick as he possibly can to a point where he must plant his leg and stabilize the momentum to transfer it to the Javelin. Watch the video!

A Pitcher is not allowed to run to develop the momentum so we must do what ever we can to develop the momentum on the mound. This is where you should watch AcePitcher.com’s 5 Components to Pitching. This video will show you how to develop momentum as a pitcher by using the lift leg, triple extension in the back leg and most important, stabilizing that momentum and allowing it to transfer to the ball.

How do we increase application time?

The answer to this questions will give you the final big picture to understanding top velocity. Application time means the amount of time a pitcher holds on to the ball through his full range of motion.

If a pitcher applied 6.5 pounds of pressure to the ball for .20 seconds as the arm is moving towards the target this would have more velocity than a pitcher applying 6.5 pounds of pressure to the ball for .15 seconds.

The question now is how do we hold on to the ball longer while keeping the same force applied. This is called separation. This is the 3rd Component in the Ace Pitcher Handbook. Separation, which is occurring in the picture here, is separation of the back throwing shoulder to the back hip. If you notice the back hip is almost pointing to the plate and the back shoulder is almost pointing to second base. This is important because it is building the majority of the torque developed from the lower half momentum in the core or stomach. Now when the shoulders commit to the catcher and the chest hits the wall like the picture below, the arm will have full range of motion. Notice Nolan Ryan’s arm 180 degrees behind his head. This is the increase of application time with the same force applied.

By building more torque in the core, instead of the shoulder, this is not only increasing velocity but saving the arm from serious wear and tear.

In conclusion, developing top velocity is every pitcher’s right but not every pitcher has the natural understanding of this skill. With this article, the Ace Pitcher Handbook, and some hard work it is possible for any pitcher to throw 90 plus mph.

To understand the effects of Olympic weight lifting and velocity on pitchers, you must first understand how velocity is measured. I will use Newton’s second law of motion, along with the Catapult Theory, to explain pitching velocity.

Newton’s Second Law:

States that the acceleration (velocity) of an object in motion is dependent upon two variables – the net force acting upon the object and the mass of the object. As the force of propulsion acting upon the object increases, the acceleration of the object increases. As the mass of the object increases, the acceleration of the object decreases.

Newton’s 2nd Law of Motion

a = f/m (f = force, m = mass, a = acceleration)

Let’s put this into baseball terms. Newton’s second law of motion would state that to throw a baseball 90 mph would require 6.5 pounds of pressure applied to a baseball, with a mass of 5 ounces, for two tenths of one second (.20).

6.5 pp applied to a 5 ounce baseball for .20 seconds = 90 mph fastball

Therefore to increase an 80 mph fastball to 90 mph you must either increase the force applied or the application time. The application time is how long you hold on to the ball once the force is applied. Subtracting 25% of application time forces a pitcher to increase the applied force by 33%. Increasing the application time by 10%, increased to .22 seconds, would add 10 mph to an 80 mph fastball.

80 mph fastball + 10% more application time = 90 mph fastball

* If you desire to see the formula in more detail that explains Newton’s Second Law defining the velocity of a baseball in motion then refer to Dr. Mike Marshalls article at: www.drmikemarshall.com/ChapterTwenty-Nine.html To find info scroll down to “1. The Release Velocity Formula for Baseball Pitchers.”

Catapult Theory:

The Catapult is made up of three components: the pivot, the coil and the arm. Let’s add a ball to the end of the arm to represent a baseball. To measure the velocity of the baseball, after the arm is released and the ball is in motion, we use Newton’s second law as described above. The importance of the Catapult is its relation to a pitcher at his full range of motion before launch of ball (See picture of Nolan Ryan below). If the Catapult pivot is not stable and is moving forward during release of the arm, then this will decrease the force applied to the ball at launch. In return, poor velocity. Now, if we stabilize the pivot, meaning no movement, and continue to apply the same force to the ball. When the arm is released and the ball is launched, it will reach its potential velocity. To keep force applied to the ball consistent the coil must maintain pressure on the arm during the entire delivery process.

How does Olympic lifting come into this equation?

First reason, it is the only type of lifting in the weight room that trains triple extension.

What is triple extension? This isn’t something new to the sports world. Olympic lifters have been using the term “Triple extension” for a long time. Triple extension occurs when the ankle joint extends, the knee joint extends along with the extension of the hip flexor. Visualize a long jumper in mid air like above (Notice left leg in triple extension). Also notice, in the picture to the right of Nolan Ryan, his right leg has triple extension. You can see his ankle, knee, and hip flexors in full extension. There is no weight lifting that trains the body pushing off of the ground as a single unit better than the Olympic Lifts. Triple extension plays in every sport that involves pushing off of ground.

Second reason, notice the lifter doing a split jerk at the top of the article. This is a very similar movement to pitching. More similar than any other weight training exercise. Studies have shown that athletes get better when training within their sport. This is called sport specific training.

This lifter is using triple extension to drive the weight up. Just like the pitcher driving the ball to the plate. The only difference here is the consequence of error. If the lifter losses momentum in the hips, he will drop the weight. If the pitcher losses momentum in the hips, he will throw a home run to some lucky batter.

If you want to learn about the Olympic Lifts and what they are, follow this link and watch the instructional video.

Coach Gayle Hatch Instructional Videos.

Now, how does triple extension increase velocity?

In all ways described in the Catapult theory above and Newton’s Second law, it adds both application time and force applied to ball.

First let’s explain how it increases application time, which is the most efficient way to increase velocity. Maximum application time comes from full range of motion. Example, Nolan Ryan has 180 degrees range of motion in picture above. This is the maximum possible. This means the Catapult is set to its potential, arm all the way back. For this to occur with a pitcher the hips must be pushed under the shoulders. The only way to push the hips under the shoulders is extending the back leg ankle, knee and hip flexor, also called Triple Extension, at the perfect time. With hips all the way under the shoulders, the pitcher now has reached his full range of motion, therefore increasing the application time to build or maintain force to the ball.

If the hips are lagging, the chest is leaning forward and the arm is leading the body, then minimal application time has occurred. Less range of motion therefore less potential to create more velocity.

Triple extension adds force to the ball because it aids in the momentum originally generated from the lift leg along with gravity. This only aids the momentum, if triple extension occurs, just before front foot strike. If it happens to early and the hips have not moved down the mound, then the hips open too soon. This kills the purpose of good momentum and it also kills full range of motion.

With chest out and hips under shoulders, chest and chin must remain up until launch of ball to keep pivot stable through entire delivery.

More benefits of Olympic lifting!

Not only do these lifts train Triple Extension better than any other style of lifting but it specifically trains fast twitch muscle fiber. This is what makes an athlete explosive. For pitchers and baseball players, getting stronger in the weight room has been forbidden, until the steroid area came into fruition. Now everyone is lifting. This isn’t a trend. This is because it works!

The last benefit of Olympic lifting for the pitching delivery occurs during stabilization of the front leg. Like described in the Catapult Theory, stabilization must occur to prevent decreasing force applied to ball. Therefore if the pitchers landing leg moves forward or gives away, then force is decreased to the ball. In return poor velocity. Notice Nolan Ryan in the picture here. His front leg almost triple extends. This means he is preventing instability in his front leg by holding and even extending it back into his hips. This is why he reached his top velocity.

So how do I get started?

In the weight room but first find a professionally certified Olympic Lifting Coach. These lifts take a lot of training to perform correctly, so to prevent injury. I do not recommend performing these lifts with out a proper coach supporting you. Please check with your physician before performing these lifts and remember weight is not important. Your form in the weight room and on the field is all that matters. Always sacrifice weight for good mechanics.

If you have any questions about this information please post your questions on the discussion board.

View footage of Nolan Ryans delivery in slow motion.

Weight Training and Velocity

Olympic lifting isn’t the only lifts in the weight room that will enhance performance and increase pitching velocity. They are the best lifts in the weight room for velocity but not the only ones. The Fusion system, which is the strength and conditioning program in the 3X Pitching Velocity program, includes the Olympic Lifts but also other effective lifts and exercises in the weight room for increasing velocity.